RELATED APPLICATIONS
This nonprovisional application claims the priority of provisional patent application U.S. Ser. No. 60/514,284, filed on Oct. 24, 2003, now abandoned, and is a continuation-in-part patent application that claims the benefit of non-provisional patent application U.S. Ser. No. 10/340,122, filed on Jan. 10, 2003 now U.S. Pat. No. 6,719,059, which is hereby incorporated by reference in its entirety.
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates in general to subsea well installations and in particular to a system for installing and retrieving a plug from a tubing hanger.
2. Background of the Invention
A typical subsea wellhead assembly has a high pressure wellhead housing supported in a lower pressure wellhead housing and secured to casing that extends into the well. One or more casing hangers land in the wellhead housing, the casing hanger being located at the upper end of a string of casing that extends into the well to a deeper depth. A string of tubing extends through the casing for production fluids. A Christmas or production tree mounts to the upper end of the wellhead housing for controlling the well fluid. The production tree is typically a large, heavy assembly, having a number of valves and controls mounted thereon.
One type of tree, sometimes called “conventional”, has two bores through it, one of which is the production bore and the other is the tubing annulus access bore. In this type of wellhead assembly, the tubing hanger lands in the wellhead housing. The tubing hanger has two passages through it, one being the production passage and the other being an annulus passage that communicates with the tubing annulus surrounding the tubing. Access to the tubing annulus is necessary to circulate fluids down the production tubing and up through the tubing annulus, or vice versa, to either kill the well or circulate out heavy fluid during completion. After the tubing hanger is installed and before the drilling riser is removed for installation of the tree, plugs are temporarily placed in the passages of the tubing hanger. The tree has isolation tubes that stab into engagement with the passages in the tubing hanger when the tree lands on the wellhead housing. This type of tree is normally run on a completion riser that has two strings of conduit. In a dual string completion riser, one string extends from the production passage of the tree to the surface vessel, while the other extends from the tubing annulus passage in the tree to the surface vessel. It is time consuming, however to assemble and run a dual string completion riser. Also, drilling vessels may not have such a completion riser available, requiring one to be supplied on a rental basis.
In another type of tree, sometimes called “horizontal” tree, there is only a single bore in the tree, this being the production passage. The tree is landed before the tubing hanger is installed, then the tubing hanger is lowered and landed in the tree. The tubing hanger is lowered through the riser, which is typically a drilling riser. Access to the tubing annulus is available through choke and kill lines of the drilling riser. The tubing hanger does not have an annulus passage through it, but a bypass extends through the tree to a void space located above the tubing hanger. This void space communicates with the choke and kill lines when the blowout preventer is closed on the tubing hanger running string. In this system, the tree is run on drill pipe, thus prevents the drilling rig derrick of the floating platform from being employed on another well while the tree is being run.
In another and less common type of wellhead system, a concentric tubing hanger lands in the wellhead housing in the same manner as a conventional wellhead assembly. The tubing hanger has a production passage and an annulus passage. However, the production passage is concentric with the axis of the tubing hanger, rather than slightly offset as in conventional tubing hangers. The tree does not have vertical tubing annulus passage through it, thus a completion riser is not required. Consequently the tree may be run on a monobore riser. A tubing annulus valve is located in the tubing hanger since a plug cannot be temporarily installed and retrieved from the tubing annulus passage with this type of tree.
In the prior art conventional and concentric tubing hanger types, the tubing hanger is installed before the tree is landed on the wellhead housing. The tubing is typically run on a small diameter riser through the drilling riser and BOP. Before the drilling riser is disconnected from the wellhead housing, a plug is installed in the tubing hanger as a safety barrier. The plug is normally lowered on a wireline through the small diameter riser. Subsequently, after the tree is installed, the plug is removed through the riser that was used to install the tree.
SUMMARY OF THE INVENTION
In this invention, a lift line deployable apparatus is provided for installing or retrieving a plug in a passage of a subsea wellhead assembly. The apparatus for engaging a plug in a passage of a subsea wellhead assembly includes a tubular housing adapted to be lowered to a subsea well. The housing has a closed upper end. A stem is carried within the housing. The stem is moveable between extended and retracted positions within the housing and the subsea wellhead assembly. The stem has a piston portion defining a piston chamber above the stem within the housing. The piston portion is preferably formed by the upper surface of the stem. A fluid chamber is located within the stem below the piston chamber. A tube or conduit connects to the housing and extends through the piston portion of the stem. The conduit is in fluid communication with the fluid chamber. Preferably the conduit is stationarily connected to the upper end of the housing and is in fluid communication with ports for the injection of hydraulic fluid. The stem slides relative to the conduits while moving between extended and retracted positions.
Preferably, the plug retrieval and installation apparatus has an engaging member for suspended from the stem for engagement with the plug. The engagement member has a fluid passage in communication with the fluid chamber. Preferably there are a plurality of conduits, fluid chambers, and fluid passages, with each set defining a fluid path between separate portions of the engaging member with the mandrel or upper portion of the housing. Each fluid path performs a different function when hydraulic fluid is injected into or vented therefrom.
Preferably, the mechanism for connecting the housing to the upper end of the subsea wellhead assembly is powered by an ROV. Also, the drive mechanism for the stem is preferably controlled and powered by an ROV. Further, the retrieval member preferably is hydraulically driven by the ROV.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1A and 1B comprise a vertical sectional view of a wellhead assembly constructed in accordance with this invention.
FIG. 2 is an enlarged sectional view of a portion of the wellhead assembly of FIGS. 1A and 1B, the sectional plane being different than in FIGS. 1A and 1B.
FIG. 3 is an enlarged sectional view of a portion of the wellhead assembly of FIGS. 1A and 1B.
FIG. 4 is an another sectional view of a portion of the wellhead assembly of FIGS. 1A and 1B, but shown in same sectional plane as in FIG. 2 to illustrate a tubing annulus valve in a closed position.
FIG. 5 is an enlarged sectional view of the tubing annulus valve of FIG. 4, shown in an open position and engaged by an engaging member of the production tree.
FIG. 6 is an enlarged sectional view of the tubing annulus valve of FIG. 4, shown in a closed position while a tubing hanger running tool is connected to the tubing hanger.
FIG. 7 is a sectional view of the tubing annulus valve as shown in FIG. 6, but shown in an open position.
FIG. 8 is a sectional view of the wellhead housings of the wellhead assembly of FIGS. 1A and 1B after running casing and in the process of receiving a BOP adapter.
FIG. 9 is a schematic horizontal sectional view of the wellhead housings of FIG. 8, the dotted lines showing a flowline connector arm being rotated.
FIG. 10 is a perspective view of the wellhead assembly of FIGS. 1A and 1B, after the BOP adapter of FIG. 8 has landed.
FIG. 11 is a schematic vertical sectional view of the wellhead assembly of FIGS. 1A and 1B, showing shutoff an ROV deployed plug tool mounted on the tree.
FIG. 12 is a schematic side view of the plug tool of FIG. 11, with a plug setting attachment.
FIG. 13 is a schematic sectional view of a plug retrieving attachment for the plug tool of FIG. 11, shown in a disengaged position with a plug, illustrated by the dotted lines.
FIG. 14 is a more detailed sectional view of the plug retrieving attachment of FIG. 13, shown in an engaged position.
FIG. 15 is a schematic view of a field being developed in accordance with this invention.
FIGS. 16A–16C are portions of a vertical sectional view of the ROV deployed plug tool shown in FIG. 11.
FIG. 17 is sectional view of an upper portion of the plug tool shown in FIGS. 16A–16C across another cut line.
FIG. 18 is a top plan view of the plug tool shown in FIGS. 16A–16C.
FIGS. 19A–19C is a more detailed sectional vertical view of a portion of the plug tool shown in FIGS. 16A–16C interacting with a plug for a subsea well.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Overall Structure of Subsea Wellhead Assembly
Referring to FIG. 1B, a lower portion of a wellhead assembly 11 includes an outer or low pressure wellhead housing 13 that locates on the sea floor and is secured to a string of large diameter conductor pipe 15 that extends into the well. In this embodiment, a first string of casing 17 is suspended on a lower end of outer wellhead housing 13 by a hanger 19. However, casing 17 and hanger 19 are not always suspended from the outer wellhead housing 13 and can be eliminated in many cases.
An inner or high pressure wellhead housing 21 lands in and is supported within the bore of outer wellhead housing 13. Inner wellhead housing 21 is located at the upper end of a string of casing 23 that extends through casing 17 to a greater depth. Inner wellhead housing 21 has a bore 25 with at least one casing hanger 27 located therein. Casing hanger 27 is sealed within bore 25 and secured to the upper end of a string of casing 29 that extends through casing 23 to a greater depth. Casing hanger 27 has a load shoulder 28 located within its bore or bowl.
In this embodiment, a tubing hanger 31 is landed, locked, and sealed within the bore of casing hanger 27. Referring to FIG. 2, tubing hanger 31 has a lower end that lands on load shoulder 28. A seal 30 seals between the exterior of tubing hanger 31 and the bore of casing hanger 27 above load shoulder 28. A split lock ring 34 moves from a retracted position radially outward to lock tubing hanger 31 to an internal profile in casing hanger 27. A sleeve 36, when moved axially downward, energizes seal 30 as well as pushes lock ring 34 to the locked position. Tubing hanger 31 is secured to the upper end of a string of production tubing 33. Tubing hanger 31 has a production passage 32 that is coaxial with tubing 33.
Referring to FIG. 3, inner wellhead housing bore 25 has a lower portion 25 a that has a smaller diameter than upper portion 25 b. This results in a conical generally upward facing transition portion or shoulder 25 c located between portions 25 a and 25 b. Wellhead housing bore upper portion 25 b has a grooved profile 35 formed therein above tubing hanger 31. Profile 35 is located a short distance below rim 37, which is the upper end of inner wellhead housing 21.
As shown in FIG. 1A, a Christmas or production tree 39 has a lower portion that inserts into wellhead housing 21. Production tree 39 has a production passage 41 extending through it that has an outlet port 41 a extending laterally outward. Production tree 39 has an isolation tube 43 that depends downward from its lower end and stabs sealingly into production passage 32 of tubing hanger 31. The lower end of production tree 39 extends into bore 25 of inner wellhead housing 21 to bore transition section 25 c (FIG. 3).
Referring again to FIG. 3, an orientation sleeve 44 is a part of and extends upward from tubing hanger 31. Orientation sleeve 44 is nonrotatably mounted to the exterior of the body of tubing hanger 31. Orientation sleeve 44 has a helical contour formed on its upper edge. A mating orientation sleeve 46 with a helical contour on its lower edge is secured to the lower end of production tree 39. When tree 39 is lowered into wellhead housing 21, orientation sleeve 46 engages the helical contour of orientation sleeve 46 to rotate production tree 39 and orient it in the desired direction relative to tubing hanger 31.
Tree and Wellhead Housing Internal Connector
Tree 39 includes a connector assembly for securing it to wellhead housing 21. The connector assembly includes a connector body 45 that has a downward facing shoulder 47 that lands on rim 37. Connector body 45 is rigidly attached to tree 39. A seal 49 seals between rim 37 and shoulder 47. Connector body 45 also extends downward into wellhead housing 21. A locking element 51 is located at the lower end of connector body 45 for engaging profile 35. Locking element 51 could be of a variety of types. In this embodiment, locking element 51 comprises an outer split ring that has a mating profile to groove 35. A plurality of dogs 53 located on the inner diameter of locking element 51 push locking element 51 radially outward when moved by a cam sleeve 55. Cam sleeve 55 moves axially and is hydraulically driven by hydraulic fluid supplied to a piston 57.
The connector assembly has an extended or retainer portion 59 that extends downward from connector body 45 in this embodiment. Extended portion 59 is located above and secured to orientation sleeve 44. A collar 60 is threaded to the outer diameter of extended portion 59 for retaining locking element 51 and dogs 53 with connector body 45. Alternately dogs 53 could be used to engage profile 35 and locking element 51 omitted. In that case, windows could be provided for the dogs in connector body 45, and extended portion 59 and collar 60 would be integrally formed with connector body 45.
Referring to FIG. 1A, a control fluid passage 61 extends through tree 39 to an exterior side portion for supplying control fluid. Although not shown, there are a number of these passages, and they lead to connector tubes on the lower end of tree 39. The connector tubes stab into mating passages on the upper end of tubing hanger 31. These passages lead to hydraulic control lines that are not shown but extend below tubing hanger 31 on the outside of production tubing 33. These control lines lead to downhole equipment in the string of tubing 33, such as a downhole safety valve and downhole pressure and temperature monitoring devices.
At least one valve is mounted to production tree 39 for controlling fluid flow. In the preferred embodiment, the valves includes a master valve 63 and a swab valve 65 located in production passage 41. A safety shutoff valve 67 is mounted to port 41 a. The hydraulic actuator 68 for safety shutoff valve 67 is shown. Valves 63 and 65 may be either hydraulically actuated or mechanically actuated (typically by ROV).
Referring again to FIG. 1A, tree 39 has a mandrel 81 on its upper end that protrudes upward. Mandrel 81 is typically sized for receiving a connector for connection to a small diameter, lightweight riser, such as for certain workover purposes. Mandrel 81 also enables other methods of intervention.
Tubing Annulus Access
FIG. 4 illustrates a tubing annulus passage 83, which is not shown in FIG. 1B or 3 because tubing annulus passage 83 is located in a different vertical sectional plane than that shown in FIGS. 1B and 3. Tubing annulus passage 83 extends vertically through tubing hanger 31 from an upper end portion to a lower end, where it communicates with a tubing annulus 85 surrounding tubing 33. The upper and lower ends of tubing annulus passage 83 may be slightly radially offset from each other, as shown in FIG. 4. An annular void space 87 surrounds isolation tube 43 between the upper end of tubing hanger 31 and the lower end of tree 39.
A tubing annulus valve 89 is mounted in tubing annulus passage 83 to block tubing annulus passage 83 from flow in either direction when closed. Referring to FIG. 5, tubing annulus valve 89 has a stem base 91 that is secured by threads 93 to tubing annulus passage 83. A stem 95 extends upward from stem base 91 along the axis of tubing annulus passage 83. An enlarged valve head 97 forms the upper end of stem 95. Valve head 97 has a secondary resilient seal as well as a primary lip seal 99 that is made of metal in this embodiment.
A shuttle sleeve 101 is reciprocally carried in tubing annulus passage 83. While in the upper closed position shown in FIGS. 4 and 6, the upper end of sleeve 101 is a short distance below an upper end portion of tubing hanger 31. While in the lower open position, shown in FIGS. 5 and 7, sleeve 101 is in a lower position relative to valve head 97. Sleeve 101 has a reduced diameter port or seat 103 formed in its interior. Seat 103 is sealingly engaged by lip seal 99 as well as the resilient seal of valve head 97 while sleeve 101 is in the lower position.
An outward biased split ring 105 is mounted to the outer diameter of sleeve 101 near its upper end. Split ring 105 has a downward tapered upper surface and a lower surface that is located in a plane perpendicular to the axis of tubing annulus passage 83. A mating groove 107 is engaged by split ring 105 while sleeve 101 is in the upper, closed position. Split ring 105 snaps into groove 107, operating as a detent or retainer to prevent downward movement of sleeve 101.
FIG. 5 shows an engaging tool or member 109 extending into the upper end of tubing annulus passage 83 into engagement with the upper end of sleeve 101. Engaging member 109 is a downward extending component of tree 39 (FIG. 1A) and is used for moving sleeve 101 from the upper to the lower position. A second identical engaging member 109′, shown in FIGS. 6 and 7, is mounted to a running tool 111 used to run tubing hanger 31. Engaging member 109 has a lip 113 on its lower end that mates with the upward facing taper on split ring 105. Lip 113 slides over and causes split ring 105 to contract, enabling engaging member 109 to push sleeve 101 downward to the open position. A spring 115, which may be a plurality of Belleville washers, is located between stem base 91 and the lower end of sleeve 101. Spring 115 urges sleeve 101 to the upper closed position. Any pressure in passage 83 would assist spring 155 in moving sleeve 101 to the closed position.
Engaging member 109 is secured to the lower end of an actuator 117, which is mounted in tree 39. Actuator 117 is a hollow, tubular member with open ends reciprocally carried in a tubing annulus passage 118 in tree 39 (FIG. 3). Actuator 117 has a piston portion on its exterior side wall that is selectively supplied with hydraulic fluid for moving actuator 117 between upper and lower positions. Tubing annulus passage 118 extends through tree 39 to an exterior side portion of tree 39 for connection to a tubing annulus line that leads typically to a subsea manifold or an umbilical that serves the tree. Tubing annulus passage in tree 118 does not extend axially to the upper end of tree 39.
When actuator 117 is moved to the lower position, engaging member 109 engages and pushes sleeve 101 from the closed position to the open position. FIGS. 6 and 7 show a similar actuator 117′ that forms a part of running tool 111 and works in the same manner as actuator 117. Like actuator 117, actuator 117′ has a piston portion that is carried in a hydraulic fluid chamber for causing the upward and downward movement in response to hydraulic pressure. Passage 118′ leads to an exterior upper portion of running tool 111 for delivering and receiving tubing annulus fluid.
Running tool 111 has conventional features for running tubing hanger 31, including setting a seal between tubing hanger 31 and bore 25 of wellhead housing 21 (FIG. 4). Running tool 111 has a lock member 119 that is radially and outwardly expansible into a mating groove formed in an interior upward extending sleeve portion of tubing hanger 31. Lock member 119 secures running tool 111 to tubing hanger 31 while tubing 33 is being lowered into the well. Lock member 119 is energized and released by a lock member actuator 121, which is also hydraulically driven. Running tool 111 has a sleeve 123 that slides sealingly into the bore 32 of tubing hanger 31. Sleeve 123 isolates the upper end of tubing annulus passage 83 from production passage 32 (FIG. 4) in tubing hanger 31.
Orientation
Referring to FIG. 8, a ring 125 is mounted to the exterior of outer wellhead housing 13, also referred to as a conductor housing. Ring 125 has a depending funnel 127 and is selectively rotatable on outer wellhead housing 13 for orienting tubing hanger 31 and tree 39 (FIG. 3) in a desired position relative to other subsea wells and equipment. A lock pin or screw 129 will selectively lock ring 125 in the desired position. An arm bracket 131 is mounted to ring 125 for rotation therewith. Arm bracket 131 cantilever supports a horizontally extending arm 133. Arm 133 has an upward facing socket on its outer end 131. Also, a guide pin 137 protrudes upward from arm 133.
Ring 125 is normally installed on outer wellhead housing 13 at the surface before outer wellhead housing 13 is lowered into the sea. Arm 133 will be attached to arm bracket 131 below the rig floor but at the surface. After outer wellhead housing 13 is installed at the sea floor, if necessary, an ROV may be employed later in the subsea construction phase to rotate ring 125 to a different orientation.
A BOP (blowout preventer) adapter 139 is being shown lowered over inner or high pressure housing 21. BOP adapter 139 is used to orient tubing hanger 31 (FIG. 3) relative to arm 133. BOP adapter 139 is preferably lowered on a lift line after the well has been drilled and casing hanger 27 installed. The drilling riser, along with the BOP, will have been removed from the upper end of inner wellhead housing 21 prior to lowering BOP adapter 139 in place. BOP adapter 139 has a guide socket 143 that is mounted to its exterior at a point for aligning with pin 137. A funnel 141 on the lower end of BOP adapter 139 assists in lowering BOP adapter 139 over inner wellhead housing 21. Socket 143 will orient BOP adapter 139 to a position depending upon the orientation of arm 133 and pin 137. An ROV (not shown) will be used to assist guide socket 143 in aligning with guide pin 137.
BOP adapter 139 has a plurality of dogs 145 that are hydraulically energized to engage an external profile on inner wellhead housing 21. BOP adapter 139 also has seals (not shown) that seal its bore to bore 25 of wellhead housing 21. A helical orienting slot 147 is located within the bore of BOP adapter 139. Slot 147 is positioned to be engaged by a mating pin or lug on running tool 111 (FIG. 6) for tubing hanger 31. This engagement causes running tool 111 to orient tubing hanger 31 in a desired orientation relative to the orientation of arm 133.
FIG. 10 is a perspective view showing BOP adapter 139 in position on inner wellhead housing 21, which is not shown in FIG. 10 because it is located within the bore of BOP adapter 139. BOP adapter 139 has an upper end with a mandrel 146. The drilling riser and BOP will connect to the external profile on mandrel 146 after BOP adapter 139 has been connected to inner wellhead housing 21.
Once BOP adapter 139 has oriented tubing hanger 31 (FIG. 1B), the well will typically be perforated and tested. Tubing hanger 31 must be oriented relative to the arm 133 because orientation sleeve 44 (FIG. 3) of tubing hanger 31 provides orientation to tree 39, as shown in FIGS. 1A and 1B. Tree 39 has a tree funnel 148 that slides over inner wellhead housing 21 as it is landing.
The safety shutoff valve 67 of tree 39 is connected to a flow line loop 149 that leads around tree 39 to a flow line connector 151 on the opposite side as shown in FIG. 1B. Flow line connector 151 will connect to a flow line 153 that typically leads to a manifold or subsea processing equipment. In this embodiment, flow line 153 is mounted to a vertical guide pin or mandrel 155 that stabs into guide funnel 135 to orient to tree 39. Other types of connections to flow line connector 151 could also be employed. Consequently, tree is oriented so that its flowline connector 151 will register with flowline 153.
Plug Retrieval and Installation
After tree 39 is installed, a plug 159 (FIG. 12) must be removed from a plug profile 157 located within tubing hanger 31, as shown in FIG. 11. Plug 159 maintains pressure that is within tubing 33 after BOP adapter 139 (FIG. 10) is removed and prior to installing tree 39 (FIG. 1A). Plug 159 is conventional and has one or more seals 161 that seal within production passage 41 of tubing hanger 31. Plug 159 has a plurality of locking elements 163 that will move radially outward between a retracted and an extended position. Locking elements 163 engage a mating groove in profile 157.
Preferably, rather than utilizing wireline inside a workover riser, as is typical, an ROV deployed plug tool 165 is utilized. Plug tool 165 does not have a riser extending to the surface, rather it is lowered on a lift line. Plug tool 165 has a hydraulic or mechanical stab 167 for engagement by ROV 169. The housing of plug tool 165 lands on top of tree mandrel 81. A seal retained in plug tool 165 engages a pocket in mandrel 81 of tree 39. When supplied with hydraulic pressure or mechanical movement from ROV 169, a connector 171 will engage mandrel 81 of tree 39. Similarly, connector 171 can be retracted by hydraulic pressure or mechanical movement supplied from ROV 169. Once connected, any pressure within mandrel 81 is communicated to the interior of the housing of plug tool 165. Prior to connection, valve 65 would normally be closed and plug 159 would also provide a pressure barrier.
Plug tool 165 has an axially movable stem 173 that is operated by hydraulic pressure supplied to a hydraulic stab 174. Stem 173 moves from a retracted position, wholly within the housing of plug tool 165 to an extended position in the proximity of plug profile 157. A retrieving tool 175 is located on the lower end of stem 173 for retrieving plug 159. Similarly, a setting tool 177 may be attached to stem 173 for setting plug 159 in the event of a workover that requires removal of tree 39. Setting tool 177 may be of a variety of types and for illustration of the principle, is shown connected by shear pin 179 to plug 159. Once locking elements 163 have engaged profile 157, an upward pull on stem 173 causes shear pin 179 to shear, leaving plug 159 in place.
Retrieving tool 175, shown in FIGS. 13 and 14, may also be of a variety of conventional types. In this embodiment, retrieving tool 175 has a body 181 that inserts partially into a receptacle 183 in plug 159. A locator sleeve 185 on the exterior of body 181 will land on the rim of receptacle 183. A collet 187 is located within locator sleeve 185 and protrudes below a selected distance. When locator sleeve 185 has landed on the rim of plug 159, collet 187 will be aligned with a groove 189 within the plug 159.
Collet 187 and sleeve 185 are joined to a piston 191. Piston 191 is supplied with hydraulic fluid from ROV 169 (FIG. 10) via one of the stabs 174. A spring 193 is compressed while retrieving tool 175 is in the released position, shown in FIG. 13. Spring 193 urges piston 191 to a lower position. When hydraulic pressure is relieved at passage 192, spring 193 will cause body 181 to move upward to the position shown in FIG. 14. In this position, a wall portion 194 of body 181 will locate directly radially inward of collet 187, preventing collet 187 from disengaging from profile 189. Once retrieving tool 175 is attached to plug 159, ROV 169 will actuate one of the hydraulic stabs or mechanical interfaces 174 to cause stem 173 (FIG. 11) to move upward. Collet 187 causes dogs 163 to be radially retractable during this upward movement as plug 159 is disengaged. Once plug 159 is above tree valve 65, tree valve 65 may be closed, enabling the entire assembly of plug tool 165 to be retrieved to the surface with a lift line.
Field Development
FIG. 15 schematically illustrates a preferred method for developing a field having a plurality of closely spaced wellhead assemblies 11. This method is particularly useful in water that is sufficiently deep such that a floating platform 195 must be utilized. Platform 195 will be maintained in position over the wells by various conventional means, such as thrusters or moorings. Platform 195 has a derrick 197 with a drawworks 199 for drilling and performing certain operations on the wells. Platform 195 also has a drilling riser 201 that is employed for drilling and casing the wells. Drilling riser 201 is shown connected to high pressure housing 21 of one wellhead assembly 11. Drilling riser 201 has a blowout preventer 203 within it. In the particular operation shown, a string of drill pipe 205 is shown extending through riser 201 into the well.
Platform 195 also preferably has a crane or lift line winch 207 for deploying a lift line 209. Lift line 207 is located near one side of platform 195 while derrick 197 is normally located in the center. Optionally, lift line winch 207 could be located on another vessel that typically would not have a derrick 197. In FIG. 14, a tree 39 is shown being lowered on lift line 209.
Drilling and Completion Operation
In operation, referring to FIG. 8, outer housing 13 along with ring 125 and arm 133 are lowered into the sea. Outer housing 13 is located at the upper end of conductor 15, which is jetted into the earth to form the first portion of the well. As conductor 15 nears the seabed, the entire assembly and arm 133 will be set in the desired position. This position will be selected based on which way the field is to be developed in regard to other wells, manifolds, subsea processing equipment and the like. Once conductor 15 has been jetted into place and later in the subsea construction program, the operator may release lock pins 129 and rotate ring 125 to position arm 133 in a different orientation. This subsequent repositioning of arm 133 is performed as necessary or as field development needs change to optimize connection points for the well flowline jumpers.
The operator then drills the well to a deeper depth and installs casing 117, if such casing is being utilized. Casing 117 will be cemented in the well. The operator then drills to a deeper depth and lowers casing 23 into the well. Casing 23 and high pressure wellhead housing 21 are run on drill pipe and cemented in place. No orientation is needed for inner wellhead housing 21. The operator may then perform the same steps for two or three adjacent wells by repositioning the drilling platform 195 (FIG. 15).
The operator connects riser 201 (FIG. 15) to inner wellhead housing 21 and drills through riser 201 to the total depth. The operator then installs casing 29, which is supported by casing hanger 27. In some cases, an additional string of casing would be installed with the well being drilled to an even greater depth.
The operator is then in position to install tubing hanger 31 (FIG. 1B). First, the operator disconnects drilling riser 201 (FIG. 15) and BOP 203 and suspends it off to one side of wellhead assembly 11. The operator lowers BOP adapter 139 on lift line 209 over inner wellhead housing 21, as illustrated in FIG. 8. With the aid of an ROV, socket 143 is positioned to align with pin 137. BOP adapter 139 is locked and sealed to inner wellhead housing 21. BOP adapter 139 may have been previously installed on an adjacent well left temporarily abandoned.
The operator then attaches drilling riser 201, including BOP 203, (FIG. 15) to mandrel 146 (FIG. 10) of BOP adapter 139. The operator lowers tubing 33 and tubing hanger 31 through drilling riser 201 on running tool 111 (FIG. 6), which is attached to a tubing hanger running string, which is a small diameter riser. Once running tool 111 is connected to tubing hanger 31, actuator 117′ is preferably stroked to move engaging member 109′ downward, thereby causing shuttle sleeve 101 to move downward. This opens tubing annulus passage 83 for upward and downward flow. Running tool 111 has a retractable pin (not shown) that engages BOP adapter guide slot 147 (FIG. 8), causing it to rotate tubing hanger 31 to the desired position as it lands within casing hanger 27.
After tubing hanger 31 has been set, the operator may test the annulus valve 89 by stroking actuator 117′ upward, disengaging engaging member 109 from sleeve 101 as shown in FIG. 6. Spring 115 pushes sleeve 101 to the upper closed position. In this position, valve head seal 99 will be engaging sleeve seat 103, blocking flow in either the upward or downward direction. While in the upper position, detent split ring 105 engages groove 107, preventing any downward movement.
The operator then applies fluid pressure to passage 118′ within running tool 111. This may be done by closing the blowout preventer in drilling riser 201 on the small diameter riser above running tool 111. The upper end of passage 118′ communicates with an annular space surrounding the small diameter riser below the blowout preventer in drilling riser 201. This annular space is also in communication with one of the choke and kill lines of drilling riser 201. The operator pumps fluid down the choke and kill line, which flows down passage 118′ and acts against sleeve 101. Split ring 105 prevents shuttle sleeve 101 from moving downward, allowing shutoff the operator to determine whether or not seals 99 on valve head 97 are leaking.
The well may then be perforated and completed in a conventional manner. In one technique, this is done prior to installing tree 39 by lowering a perforating gun (not shown) through the small diameter riser in the drilling riser 201 (FIG. 15) and through tubing 33. The smaller diameter riser may optionally include a subsea test tree that extends through the drilling riser.
If desired, the operator may circulate out heavy fluid contained in the well before perforating. This may be done by opening tubing annulus valve 89 by stroking actuator 117′ and engaging member 109′ downward. Engaging member 109′ releases split ring 105 from groove 107 and pushes sleeve 101 downward to the open position of FIG. 7. A port such as a sliding sleeve (not shown) at the lower end of tubing 33 is conventionally opened and the blowout preventer in drilling riser 201 is closed around the tubing hanger running string. The operator may circulate down the running string and tubing 33, with the flow returning up tubing annulus 85 into drilling riser 201 and up a choke and kill line. Reverse circulation could also be performed.
After perforating and testing, the operator will set plug 159 (FIG. 12) in profile 157 (FIG. 11) in tubing hanger production passage 32. Typically, plug 159 is set by lowering it on wireline through the small diameter riser. Tubing annulus valve 89 is closed to the position of FIG. 6 by stroking actuator 117′ upward, causing spring 115 to move sleeve 101 upward. The operator then retrieves running tool 111 on the running string through the blowout preventer and drilling riser 201. The downhole safety valve (not shown) in tubing 33 is above the perforations and is preferably closed to provide a first pressure barrier; plug 159 in tubing hanger production passage 32 providing a second pressure barrier. Tubing annulus 85 normally would have no pressure, and tubing annulus valve 89 provides a temporary barrier in the event pressure did exist.
The operator then retrieves running tool 111 (FIG. 6) on the small diameter riser. The operator releases drilling riser 201 and BOP 203 from BOP adapter 139 (FIG. 8) and retrieves BOP adapter 139 on lift line 209 (FIG. 15) or deploys BOP adapter 139 on an adjacent well. The operator may then skid platform 195 sequentially over the other wells for performing the same functions with BOP adapter 139 and drilling riser 201 for a different well. Once tubing 29 has been run and perforated, there is no more need for drilling riser 201 or derrick 197 (FIG. 15). Even though platform 195 may have skidded out of alignment with the particular well, an ROV can guide lift line 209 down to engage and retrieve or move BOP adapter 139.
The operator is now in position for running tree 39 on lift line 209 (FIG. 15). Tree 39 orients to the desired position by the engagement of the orienting members 44 and 46 (FIG. 3). This positions tree connector 151 in alignment with flowline connector 153, if such had already been installed, or at least in alignment with socket 127. Flowline connector 153 could be installed after installation of tree 39, or much earlier, even before the running of high pressure wellhead housing 21. As tree 39 lands in wellhead housing 21, its lower end will move into bore 25 of wellhead housing 21, and isolation tube 43 will stab into production passage 32 of tubing hanger 31. While being lowered, orientation member 44 engages orientation sleeve 46 to properly orient tree 39 relative to tubing hanger 31. Once landed, the operator supplies hydraulic fluid pressure to cam sleeve 55, causing dogs 53 to push locking element 51 (FIG. 2) to the outer engaged position with profile 35. Flowline connector 151 (FIG. 1B) of tree 39 aligns with flowline connector 153, and the tubing annulus passage (not shown) in tree 39 is connected to a manifold or a related facility.
Referring to FIGS. 11–13, in a preferred technique, with lift line 209 (FIG. 15) and the assistance of ROV 169, the operator lowers and connects plug tool 165 to tree mandrel 81. The operator opens valve 65 and removes plug 159 in tubing hanger 31 with retrieval tool 175. Tree valve 65 is closed once plug 159 is above it. Plug tool 165 and plug 159 may then be retrieved and a tree cap installed, typically using ROV 169. Tree 39 should be ready for production.
Referring to FIG. 5, during production, tubing annulus valve 89 may remain closed, but is typically held open for monitoring the pressure in tubing annulus 85. If tubing annulus valve 89 is closed, it can be opened at any time by stroking actuator 117 (FIG. 5) of tree 39 downward. Any pressure within tubing annulus 85 is communicated through tubing annulus passage 118 in tree 39 and to a monitoring and bleedoff facility.
For a workover operation that does not involve pulling tubing 33, a light weight riser with blowout preventer may be secured to tree mandrel 81. An umbilical line would typically connect the tubing annulus passage on tree 39 to the surface vessel. Wireline tools may be lowered through the riser, tree passage 41 and tubing 33. The well may be killed by stroking actuator 117 (FIG. 5) downward to open tubing annulus valve 89. Circulation can be made by pumping down the riser, through tubing 33, and from a lower port in tubing 33 to tubing annulus 85. The fluid returns through tubing annulus passage 83 and passage 118 in tree 39 to the umbilical line.
For workover operations that require pulling tubing 33, tree 39 must be removed from wellhead housing 21. A lightweight riser would not be required if tubing hanger plug 159 (FIG. 12) is reset into profile 157 of tubing hanger 31 with plug tool 165 (FIG. 11). The operator installs plug tool 165 using lift line 209 (FIG. 15) and ROV 169. Plug 159 is attached to stem 173 and retrieval tool 177 by shear pin 179 and lowered into profile 157. Once locking elements 163 latch into profile 157, the operator pulls upward, releasing retrieval tool 177 from plug 159 by shearing pin 179. The downhole safety valve in tubing 33 typically would be closed during this operation. Tree 39 is retrieved on lift line 209 with the assistance of ROV 169. Then drilling riser 201 (FIG. 15) is lowered into engagement with inner wellhead housing 21. The operator retrieves tubing 33 and performs the workover in a conventional manner.
Detailed Description of the Plug Tool
Referring to FIGS. 16A–C and 19A–C, the preferred embodiment of plug tool 165′ is shown engaging a conventional plug 159′. Plug tool 165′ preferably includes a housing 211, which in the preferred embodiment comprises an upper portion 211A and a lower portion 2111B. In the alternative, housing 211 may also be formed of a single housing body. Housing 211 is preferably tubular in shape to surround and enclose axially moveable stem 173′. In the preferred embodiment, a cover plate 212 connects to the upper end of housing 211 and forms an upper portion of plug tool 165′. As shown in FIGS. 16A and 18, cover plate 212 preferably covers the circular cross sectional area of plug tool 165′ across the top portion of housing 211 and extends radially outward from a side of housing 211. Axially moveable stem 173′ preferably includes an upper piston 213 and a lower piston 215, both of which are enclosed by housing 211. Upper piston 213 preferably includes an upper portion 217. Upper piston 213 is releasably held in an upper position by a shear pin 214, which is sheared when sufficient hydraulic pressure is supplied to an upper piston chamber 219. The interior surface of housing 211, the lower surface of cover plate 212, and upper portion 217 define piston chamber 219, which is above upper piston 215 and below cover plate 212 within housing 211. A fluid port 220, extending through a side of housing 211, is in fluid communication with upper piston chamber 219. Hydraulic fluid is transmitted through port 220 into and out of upper piston chamber 219 to actuate upper piston 213 between extended and retracted positions. Upper piston 213 is shown in FIGS. 16A, 16B, and 16C in its extended position.
In the preferred embodiment, upper piston 213 is preferably tubular in shape below upper portion 217. Upper piston 213 surrounds and encloses lower piston 215 while lower piston 215 is in its retracted position. Upper piston 213 encloses a portion of lower piston 215 while lower piston 215 is in its extended position, as shown in FIGS. 16A–C. Lower piston 215 preferably includes an upper portion 221, which is the portion enclosed by and engaging the interior surface of upper piston 213 as shown in FIGS. 16A and 16B. The lower surface of upper portion 217 of upper piston 213, the interior surface of upper piston 213, and the upper surface of upper portion 221 of lower piston 215 define an inner piston chamber 223. Lower piston 215 is releasably held in the upper retracted position by a shear pin 224 that shears when sufficient pressure is supplied to inner piston chamber 223. Lower piston 215 actuates between its retracted and extended positions as hydraulic pressure increases and decreases within inner piston chamber 223. A piston passage 225 preferably extends from upper piston chamber 219 to inner piston chamber 223 through upper portion 217 of upper piston 213. Hydraulic fluid injected through fluid port 220 increases pressure within upper piston chamber 219 until upper piston 213 slides axially downward to its extended position. As hydraulic pressure increases within upper piston chamber 219, the hydraulic fluid flows through piston passage 225 into inner piston chamber 223. As the hydraulic pressure within inner piston chamber 223 increases, lower piston 215 begins to slide axially downward to its extended position shown in FIGS. 16A–C. Likewise, a fluid port 228 extends through a side of housing 211 at a location below lower piston 215 for actuating lower and upper pistons 215, 213 to their respective retracted postions by increasing the hydraulic pressure below lower piston 215.
Referring to FIG. 16C, lower piston 215 preferably includes a lower piston adapter 227 located toward the axially lowermost portion of lower piston 215. A retrieval tool 175′ connects to and is suspended from lower piston 215 with lower piston adapter 227. Lower piston adapter 227 includes an upper portion having an outer circumference substantially the same as the portion of lower piston 215 located above lower piston adapter 227, and a lower portion having an outer circumference that is less than the outer circumference of lower piston 215. Retrieval tool 175′ preferably extends axially downward until and in close proximity with a plug 159 located within tubing hanger 32. Retrieval tool 175′ provides an operator with a device for inserting and removing a conventional plug 159′ within tubing hanger 32.
Referring to FIG. 17, plug tool 165′ preferably includes a provision, typified by shackle assembly 229 attached to cover plate 212. Shackle assembly 229 extends above plug tool 165′ and makes provision for suspension plug tool 165′ from a cable. Shackle assembly 229 advantageously provides an operator a way of lowering plug tool 165′ to subsea wellhead assembly 11 on a cable or line rather than using a riser.
Referring to FIG. 16A and FIG. 18, a port 231 extends through a side of cover plate 212 toward the axial centerline of plug tool 165′. Port 231 provides an opening for hydraulic fluid to enter plug tool 165′ for actuating various tasks performed by plug tool 165′. Port 231 preferably extends radially inward toward the axial centerline of plug tool 165′ so that port 231 is in fluid communication with a tubular member 233 located within plug tool 165′. Tubular member 233 extends axially downward from cover plate 212 within housing 211. Tubular member 233 extends through upper piston chamber 219 and upper piston 213, while also extending through upper portion 221 of lower piston 215. In the preferred embodiment, the lower end of tubular member 233 is located within passage 239 formed within and axially extending through lower piston 215.
Preferably, port 231 communicates with tubular member 233 through a bolt 235 having axial and lateral passages. As will be appreciated by those skilled in the art, port 231 can communicate with tubular member 233 in a variety of ways. Tubular member 233 preferably extends through upper portion 217 of upper piston 213 through a bore 237 formed in upper portion 217. Tubular member 233 sealingly engages bore 237. Upper piston 213 slidingly engages tubular member 233 as upper piston 213 moves between extended and retracted positions. Tubular member 233 preferably extends through and sealingly engages a bore 238 formed in upper portion 221 of lower piston 215. The outer surface of tubular member 233 slidingly engages bore 238 of lower piston 215 as the lower piston moves between its extended and retracted positions.
Tubular member 233 has a tubular member bore 240 that is in fluid communication with port 231 through bolt 235, and with passage 239 formed within lower piston 215. Fluid flow is provided by an ROV so that hydraulic fluid enters port 231 and flows through bolt 235 into tubular member bore 240 of tubular member 233, for communication with various portions of plug tools 165′ located below lower piston 215 and performing various tasks with plug tool 165′
In the preferred embodiment, a passageway connector 241 is located at a lower end of passage 239, which sealingly engages with the bore of passage 239 within lower piston 215 and matingly engages lower piston adapter 227. A fluid passage 245, formed within lower piston adapter 227, is in fluid communication with the central bore of passage connector 243. Fluid passage 245 extends axially downward from passage connector 243 to retrieval tool 175′.
In the preferred embodiment, there are a plurality of stab ports 231 for performing various tasks with retrieval tool 175′. As shown in FIG. 18, there are preferably four stab ports 231 extending from a radial edge of cover plate 212 toward the axial centerline of plug tool 165′. The various stab ports 231 are designated with 231A, 231B, 231C, and 231D, and each transmits hydraulic fluid for performing specific tasks with plug tool 165′. In the preferred embodiment, there are also a plurality of tubular members 233. Preferably there are the same number of tubular members 233 as there are stab ports 231. As shown in FIG. 18, stab ports 231A, 231B, 231C, and 231D engage respective tubular members 233A, 233B, 233C, and 233D. Referring to FIGS. 16A and 16B, tubular members 233A and 233B are the only tubular members 233 shown due to the cross sectional cut line of FIGS. 16A and 16B. In the preferred embodiment, fluid passage 245 also comprises a plurality of fluid passages 245A, 245B, 245C (not shown), and 245D (not shown), which are each in fluid communication with their respective tubular members 233 and stab ports 231. Fluid passage 245A, 245B, 245C, and 245D preferably extend axially downward through lower piston adapter 227 to retrieval tool 175′ for communicating hydraulic fluid with a plurality of fluid passages 247 formed in retrieval tool 175′.
Referring to FIGS. 16C and 19A–C, fluid passages 247 preferably include a plurality of fluid passages 247A, 247B, 247C, and 247D, which are all in fluid communication with their respective fluid passages 245A, 245B, 245C, and 245D within lower piston adapter 227. Due to the cross sectional cut in FIG. 16C, not all fluid passages 245, 247 are shown in FIG. 16C. However, fluid passages 247A, 247B, 247C, and 247D are shown in FIGS. 19A–C. Each fluid passage 247A, 247B, 247C, and 247D extends axially downward for providing hydraulic fluid to lower portions of retrieval tool 175′.
As best shown in FIGS. 19A–C, in the preferred embodiment, a latch piston 249 is centrally located within retrieval tool 175′. Latch piston 249 preferably includes an upper portion having a larger cross sectional diameter than a lower portion. The upper portion with a large cross sectional diameter preferably slidingly engages an interior surface of retrieval tool 175′, while a lower portion of latch piston 249 slidingly engages the interior surface of the lower portion of retrieval tool 175′. A latch piston chamber 251 is preferably formed between latch piston 249 and an interior surface of retrieval tool 175′.
Fluid passage 247A extends axially downward through retrieval tool 175′ and is in fluid communication with an upper surface of latch piston 249. When hydraulic fluid is transmitted through 247A, hydraulic pressure builds in piston chamber 251 above latch piston 249 to move latch piston 249 axially downward. Fluid passage 247B extends axially downward through retrieval tool 175′ so that fluid passage 247B is in fluid communication with latch piston chamber 251 below the upper portion of latch piston 249. As hydraulic fluid is transmitted from fluid passage 247B into latch piston chamber 251, an increase in hydraulic pressure in latch piston chamber 251 causes latch piston 249 to slide axially upward. Accordingly, latch piston 249 is actuated between its upper and lower positions through the selective transmission of hydraulic fluid through fluid passages 247A or 247B.
In the preferred embodiment, a plurality of latches 253 extend axially downward from retrieval tool 175′. Preferably, latches 253 are positioned between an outer portion of retrieval tool 175′ and latch piston 249. Each latch 253 includes a lower portion 255 which pivots radially inward and outward as latch piston 249 slidingly engages an interior surface of each latch 253. As shown in FIGS. 19A–C, lower portion 255 is pushed radially outward as a lower portion of latch piston 249 slidingly engages the interior surface of lower portion 255 of latches 253. Preferably, lower portion 255 includes an upward facing profile formed around its outer circumference.
As shown in FIG. 16C, when a lower surface of retrieval tool 175′ abuts an upper surface of plug 159′, latches 253 extend axially downward within a portion of plug 159′. Preferably, a downward facing profile 254 is formed within plug 159′ that matingly engages lower portion 255 of latches 253 when latches 253 are pushed radially outward by latch piston 249. Latch piston 249 locks retrieval tool 175′ with plug 159′ by pushing latches 253 radially outward and engaging downward facing profile 254 with lower portion 255 of latches 253 when latch piston 249 slides axially downward upon hydraulic fluid being transmitted by fluid passage 247A. The engagement of downward facing profile 254 and lower portion 255 of latches 243 is enough so that plug tool 165′ can use retrieval tool 175′ to lift plug 159 after plug 159 has been disconnected or unlocked from tubing hanger 32.
In the preferred embodiment, plug 159′ preferably includes a plug adapter 257 located toward an upper portion of plug 159′ for engagement with retrieval tool 175′. Preferably, plug adapter 257 has a larger cross sectional diameter towards its upper portion than its lower portion. The lower portion of plug adapter 257 preferably has a sloped surface 263 so that an upper portion of the sloped surface 263 has a larger cross sectional diameter than the lower portion of the sloped surface 263. Plug adapter 257 preferably engages a plug lock assembly 259 formed around a lower portion of plug adapter 257. Plug adapter 257 slidingly engages plug lock assembly to lock and unlock plug 159′ within the well. Plug lock assembly 259 preferably includes a plug lock sleeve 261 which receives and engages the lower portion of plug adapter 257. Plug lock sleeve 261 also preferably includes an inner receiving portion 264 which slidingly engages sloped surface 263 of plug 257. The inner receiving portion is preferably formed along an inner surface of a plurality of dogs 265 and extend radially outward from plug 159. As sloped surface 264 slides axially downward relative to inner receiving portion 263, dogs 265 are pushed radially outward for engagement with the well. As plug adapter 257 and sloped surface 263 slides axially upward relative to dogs 265 and inner receiving portion 264, dogs 265 are allowed to retract radially inward for disengagement from the well. Accordingly, actuation of plug adapter 257 axially upward and downward relative to the remainder of plug 159′ locks and unlocks plug 159′ within the well.
In the preferred embodiment, retrieval tool 175′ includes a stinger 269 extending axially downward toward the centerline of plug 159′ through plug adapter 257. Preferably, stinger 269 protrudes axially through plug adapter 257, in a manner known in the art, for engaging an equalizing sleeve assembly 270 for allowing pressure below and above plug 159′ to equalize the pressures within plug 159′ and outside of plug 159′ for removal from wellhead assembly 11. Preferably, a lower portion of stinger 269 engages the equalizing assembly 270 so that fluid communicates between the interior and exterior of plug 159′ through an equalization port 272. Equalization port 272 is closed when stinger 269 is not engaging equalizing assembly 270. A stinger mandrel 273 located axially within plug adapter 257 guides stinger 269 through plug adapter 257 axially downward toward equalizing assembly 270 located in a lower portion of plug 159′ for the lower tip of stinger to engage equalizing assembly for balancing fluid pressures.
Stinger mandrel 273 is preferably tubular in shape with an upper portion having a first cross-sectional diameter, and a lower portion having a second cross-sectional area. The first cross-sectional diamter being larger than the second. A downward facing shoulder 283 is formed at the interface of the upper portion with the first cross-sectional diameter and the lower portion with the second cross-sectional diameter. The lower portion with the second cross-sectional diameter slidingly engages a lower portion of plug adapter 257. An upward facing 285 shoulder is formed on the lower portion of plug adapter for engaging downward facing shoulder of mandrel 273. Stinger mandrel 273 cannot slide axial downward relative to plug adapter 257 when upward and downward facing shoulders 285, 283 are in engagement.
An upward facing ledge 276 is formed on the interior surface of stinger mandrel 273. A downward facing ledge 274 is formed on the outer surface of stinger 269. As best shown in FIGS. 19A, 19B, ledges 274, 276 do not engage each other when retrieval tool 175′ initial lands on plug 159′ and stinger 269 is initially inserted within stinger mandrel 273. Ledges 274 engage each other after piston 249 slides an intermediate stroke the to the position shown in FIG. 19B, upon piston chamber 251 receiving hydraulic fluid from passage 247A. As more fluid is injected into piston chamber 251 through passage 427A, piston 249 continues to push downward on stinger 269. Stinger 269 cannot slide axially downward relative to stinger mandrel 273, which is fixedly secured to plug 159′ below plug adaptor 257. Therefore, plug adaptor 257 and the outer portion of retrieval tool 175′ slide axially upward relative to stinger 269 and the lower portion of plug 159′ with continued actuation of piston 249. As best shown in FIGS. 19B, 19C, this action causes plug adapter 257 to slide upward relative to dogs 265 in plug lock assembly 259, which allows dogs 265 to disconnect from tubing hanger 32.
An upper ledge 271 is preferably formed to an upper end of stinger mandrel 273 for engagement with retrieval tool 175′. Upper ledge 271 preferably has a larger cross-section than the portion of stinger mandrel immediately below ledge 271. Retrieval tool 175′ preferably includes a latch sleeve 279 that is located radially within latch piston 249. The latch sleeve slidingly engages an interior of latch piston 249 in axially upward and downward directions. Latch sleeve 279 defines a piston chamber 281 within latch piston 249. As shown in FIGS. 16C and 19A–C, fluid passage 247D extends axially downward through retrieval tool 175′ and is in fluid communication with piston chamber 281 below a portion of latch sleeve 279. Fluid passage 247C extends axially downward through retrieval tool 175′ and is in fluid communication with piston chamber 281 above a portion of latch sleeve 279. As hydraulic fluid is injected below latch sleeve 279, latch sleeve 279 is actuated axially upward relative to stinger 269 and within latch piston 249. As hydraulic fluid is transmitted into piston chamber 281 above latch sleeve 279, latch sleeve 279 actuates axially downward relative to latch piston 249 and stinger 269.
A plurality of inner latches 277 are located within latch sleeve 279. The plurality of inner latches are preferably arranged so that the enlarged stinger mandrel head, or upper ledge 271 of stinger 269 is housed within inner latches 277 when retrieval tool 175′ engages plug 159′. In the preferred embodiment, inner latches 277 include a lower portion 278 that engage stinger mandrel 273 below enlarged upper ledge 271, to thereby lock stinger mandrel 273 so that any movement of retrieval tool 175′, with latch sleeve 279, also causes axial movement of stinger mandrel 273 and the lower portion plug 159′. Lower portion 278 of inner latches 277 are actuated radially inward and outward relative to stinger 269 through the axially upward and downward movements of latch sleeve 279. Accordingly, retrieval tool 175′ locks to and engages with stinger mandrel 273 upon sliding latch sleeve 279 axially downward relative to stinger mandrel 273, and unlocks by sliding latch sleeve 279 axially upward relative to stinger mandrel 273. During retrieval, the engagement of latches 277 and upper ledge 271 of mandrel 273 provides a back-up connection between tool 175′ and plug 159′. During installation procedures, with both pistons 249, 279 extended, retrieval tool can push plug 159′, through mandrel 273, into sealing engagement with tubing hanger 32. After positioning plug 159′ the operator can actuate piston 249 upward, which causes plug adapter 257 to slide axially downward relative to mandrel 273 to thereby slide lock dogs 265 radially outward with sloped surface 263. Upon actuation of upper piston 249, dogs 265 lock plug 159′ into engagement with tubing hanger 32.
For retrieval operations, in operation, plug tool 165′ is lowered on a cable attached to shackle assembly 229 to subsea wellhead assembly 11. Upper and lower pistons 213, 215 are preferably in their retracted positions while lowered and landed on wellhead assembly 11. Upon landing plug tool 165′ on wellhead assembly 11, an ROV actuates valves for venting port 228 and injecting hydraulic fluid through port 220 into piston chamber 219. As the hydraulic pressure in piston chamber 219 increases, upper piston 213 slides axially downward, relative to housing 211 and tubular members 233, while also pushing lower piston 215 axially downward. Upon extending a predetermined length, and engaging an inner surface of housing 211 with the lower end of upper piston 213, upper piston stops 213 sliding axially downward. A continued supply of hydraulic fluid through port 220 increases the hydraulic pressure in chamber 219, thereby causing the hydraulic fluid to flow through piston passage 225 into inner piston chamber 223. Increased pressure within inner piston chamber 223 actuates and extends lower piston 215 and retrieval tool 175′ axially downward relative upper piston 213 further toward plug 165′. Hydraulic fluid is supplied until stinger 269 slides within stinger mandrel 273 and retrieval tool 175′ engages plug 159′.
While maintaining pressure in piston chambers 219, 223, the ROV then actuates valves for injecting hydraulic fluid into ports 231A and 231C while venting ports 231B and 231D. Hydraulic fluid is injected into port 231A, through tubular member 233A, fluid passage 245A in lower piston 215, and fluid passage 247A in retrieval tool 175′, into piston chamber 251 above piston 249. Piston 249 is actuated downward an intermediate stroke between FIGS. 19A and 19B, which in turn actuates latches 253 radially outward into locking engagement with plug adapter 257. While actuating to the intermediate position shown in FIG. 19B, stinger 269 axially downward relative to stinger mandrel 273 until ledges 274, 276. Stinger 269 also engages and actuates equalizing assembly 270 so that equalization port 272 is in fluid communication with the interior of plug 159′ to balance pressures.
With continued supply of hydraulic fluid from passage 247A, piston 249 continues to slide relative to the outer portion of retrieval tool 175′. Because ledges 274, 276 prevent stinger 269 from sliding relative to stinger mandrel 273, and stinger mandrel is fixedly connected to the lower portion of plug 159′, the outer portion retrieval tool 175′ slides axially upward relative to piston 249 and pulling plug adapter 257 upward as well. As plug adaptor 257 slides axially upward relative to lock assembly 259, sloped face 264 of plug adaptor 257 slides out of engage with sloped surface 263 which allows dogs 265 to slide radially inward. Plug 165′ is unlocked from tubing hanger 32 when dogs 265 slide radially inward.
Hydraulic fluid is transmitted through port 231C, through hydraulic passage 247C, into piston chamber 281 above latch sleeve, piston 279. Once again, during this operation, port 231D is vented. Increased hydraulic pressure in chamber 281 above latch sleeve 279 actuates sleeve 279 axially downward to lock latches 277 with upper ledges 271 of mandrel 273. The engagement of latches 277 with mandrel 273 provides a secondary connection with plug 159′. Plug 159′ is then lifted or removed from wellhead assembly 11 by actuating upper and lower pistons 213, 215 to their respective retracted positions.
For actuating upper and lower pistons 213, 215 to their retracted positions, the ROV adjusts valves to vent port 220, and opening port 228. Hydraulic fluid is injected in port 228 below lower piston 215 to increased the pressure within housing 211 below lower piston 215. The increased pressure causes lower piston to slide axially upward relative to upper piston 213 while also forcing hydraulic fluid to exit inner piston chamber 223 through piston passage 225 until lower piston 215 engages upper portion 217 of upper piston 213. Continued supply of hydraulic fluid through port 228 increases the hydraulic pressure below both upper and lower pistons 213, 215 to actuate lower and upper pistons 215, 213 into their fully retracted positions while fluid in piston chamber 219 vents through port 220.
For plug installation procedures, plug 159′ is preferably already attached to retrieval tool 175′. Plug 159′ and retrieval tool 175′ are lowered toward tubing hanger 32 by extending upper and lower pistons 213, 215 in the manner described above. Having latch sleeve 279 in its extended position, as shown in FIG. 19C, allows the operator to push the lower portion of plug 159′, with stinger 269 and stinger mandrel 273, into sealing engagement with tubing hanger 32 before actuating dogs 265 into their locked position. Stinger mandrel 273 is released from latches 277 when latch sleeve 279 is actuated upward. The ROV actuates valves for venting port 231C and passage 247C while injecting fluid through port 231D and passage 247D. Hydraulic fluid flows from passage 247D into chamber 281 below latch sleeve 279 to slide latch sleeve 279 axially upward relative to latches 277, thereby unlocking latches 277 from mandrel 273.
Dogs 265 are locked, or extended radially outward by an initial upward stroke of piston 249, as shown in FIGS. 19C and 19B. The initial stroke causes the outer portion of retrieval tool 175′ to slide downward relative to piston 249 and push downward on plug adaptor 257. The downward movement of plug adaptor 257 cams dogs 265 radially outward into locking engagement with tubing hanger 32. With continued actuation of piston 249 from the position shown in FIG. 19B to the position shown in FIG. 19A, lower portion of latches 253 rotate radially inward and disengage from plug adaptor 257 to thereby unlock retrieval tool 175′ from plug 159′. Piston 249 is actuated from the position shown in FIG. 19C to the positions shown in FIG. 19B, and then on to FIG. 19A by supplying hydraulic fluid through port 231B and passage 247B while at the same time venting passage 247A and port 231A. The venting and injection through passages 247A, 247B and ports 231A, 231B are controlled by the ROV.
The invention has significant advantages. The plug tool allows a plug to be retrieved from the tubing hanger without the need for a riser extending to the surface. Since a riser is not needed, the tree can be efficiently run on a lift line. The plug tool is easily installable on a lift line. Its functions of connecting, moving the stem, and engaging the plug are accomplished by power from an ROV, avoid the need for an umbilical to the surface for the plug tool. The plug tool can also set a plug in the tubing hanger in the event a plug is needed.
While the invention has been shown in only one of its forms, it should be apparent to those skilled in the art that it is not so limited but is susceptible to various changes without departing from the scope of the invention.